An elevated sarcolemmal lactate (and proton) transport capacity is an advantage during muscle activity in healthy humans.

Abstract

The etiology of muscle fatigue remains incompletely solved especially in vivo (3). The causes of muscle fatigue vary according to the type, duration and intensity of exercise, and to the physical fitness and health status of the subjects. Nevertheless, an elevated sarcolemmal lactate (and proton) transport capacity constitutes an advantage during muscle activity. During moderate-intensity exercise, efficient lactate exchanges contribute to the cell-cell lactate shuttle i.e., the delivery of lactate for its utilization as fuel by neighboring or distant active and oxidative muscles fibers or as substrate by other tissues (e.g. for neoglucogenesis by the liver) (1). During high-intensity exercise, the lactate exchange ability was positively correlated with the capacity to prolong exercise (4). Whether this correlation between the lactate exchange ability and performance was (directly or indirectly) causal or coincidental, the question is still under debate. Nevertheless, it remains that an elevated lactate exchange ability seems to constitute a protective mechanism against muscle fatigue. Since the transport of lactate across the sarcolemma is mediated mainly by the lactate-H+ cotransport via the monocarboxylate transporters MCT1 and MCT4, an elevated lactate transport capacity delays both muscle lactate accumulation and intracellular pH decrease and seems to favor muscle activity. In accordance, previous experiments have shown that metabolic alkalosis enhances the net lactate release rate from the active muscles and work capacity (2, 5) contrary to acidosis that reduces lactate efflux from muscle and exercise tolerance (5). All this makes an elevated sarcolemmal lactate (and proton) transport capacity an advantage during muscle activity.